CN211227564U - Needle protection sheet for circular knitting machine - Google Patents

Abstract

The utility model relates to a hosiery machine field provides a protect needle piece for circular knitting machine, include: the needle guard piece comprises a needle guard piece main body (45), a needle guard piece clamping part (46) extends downwards from the front end of the needle guard piece main body (45), the needle guard piece clamping part (46) is provided with a first protrusion (461) and a second protrusion (462), and a recess (463) is formed between the first protrusion (461) and the second protrusion (462). Through the utility model discloses, can be more simple and convenient more effective transfer that realizes fabric stocking line.

Description

Needle protection sheet for circular knitting machine

Technical Field

The present invention relates to the transfer technique of fabrics, and more particularly, to a needle guard for circular knitting machines.

Background

The current circular knitting machine has a complex structure, cannot realize the full-automatic flow of the fabric from knitting, picking, transferring, seam port butting, sewing and fabric overturning devices, needs manual intervention, and greatly reduces the knitting efficiency. After the hosiery knitting machine has finished knitting the last round of hosiery, the hosiery needs to be transferred to a stitching device to sew the toe. In this case, the thread needs to be transferred from the hosiery knitting machine, generally by means of a transfer needle. Therefore, the transfer device is required to reliably transfer the sock thread in the transfer process without the phenomena of thread falling, thread hanging and the like.

SUMMERY OF THE UTILITY MODEL

In view of the problems in the background art,

the utility model discloses a protect needle piece for circular knitting machine, include: the needle guard piece clamping part is arranged at the front end of the needle guard piece main body in a downward extending mode and provided with a first bulge and a second bulge, and a recess is formed between the first bulge and the second bulge.

Optionally, the needle guard sheet body has a needle guard sheet clamping portion extending downward from a front end thereof, the needle guard sheet clamping portion has a first protrusion and a second protrusion, and a recess is formed between the first protrusion and the second protrusion.

Optionally, a needle guard beveling portion is formed at a junction between the needle guard main body and the needle guard holder, and the needle guard holder extends vertically downward from the needle guard beveling portion.

Optionally, the lower side of the rear end of the needle guard main body has a needle guard projection for engaging with an external device.

Optionally, the lower side of the needle guard body has a plurality of needle guard grooves for engaging an external device.

Optionally, the needle guard clamping portion extends vertically downward.

Optionally, the needle guard projection extends vertically downward.

The utility model has the advantages that: through the utility model discloses, can be more simple and convenient more effective transfer that realizes fabric stocking line. The needle protection sheet is used for picking up the fabric on the needle hook of the knitting needle by the transfer needle and the needle protection sheet which work cooperatively after the production of the circular knitting machine is finished. And the needle protection sheet moves up and down back and forth through the air cylinder in the picking process. When the picking is finished, the motor drives the screw rod to lift and move to a safe height, and meanwhile, the motor below drives the worm gear in the worm gear box to transversely transfer after the sock falling pipe rises to a certain height, so that the transfer of the fabric is realized.

Drawings

In order that the invention may be more readily understood, it will be described in more detail with reference to specific embodiments thereof that are illustrated in the accompanying drawings. These drawings depict only typical embodiments of the invention and are not therefore to be considered to limit the scope of the invention.

Figure 1 shows a perspective view of one embodiment of a transfer needle used in the method of the present invention.

Fig. 2 shows a perspective view of another embodiment of a transfer needle used in the method of the present invention.

Figure 3 shows a schematic view of a transfer needle used in the method of the present invention in use.

Fig. 4 shows a perspective view of another embodiment of a transfer needle used in the method of the present invention.

Figure 5 shows a perspective view of one embodiment of a needle guard used in the method of the present invention.

Figure 6 shows a perspective view of one embodiment of a slit tooth used in the method of the present invention.

Fig. 7 shows a schematic view of an angle of a tooth holder for slot tooth mounting.

Fig. 8 shows a schematic view of another angle of the tooth holder for slot tooth mounting.

Fig. 9 shows a perspective view of another angle of the slit teeth used in the method of the present invention.

Fig. 10 shows a partial structural view of a slit tooth used in the method of the present invention.

Fig. 11 shows a partial structural view of a slit tooth used in the method of the present invention.

Fig. 12 is a view showing a positional relationship among the slit teeth, the transfer needle, and the needle guard.

Fig. 13-29 show schematic views of the operation of the fabric loop pick-up and transfer of the present invention.

Reference numerals

Knitting 1, turning over 2, holding 201, sinker 201; a fabric 3; the transfer needle 4a, the transfer needle 4b, the transfer needle 4h, the needle guard piece 4c, the transfer needle main body 41, the transfer needle projection 411, the transfer portion 42, the first bifurcating piece 421, the second bifurcating piece 422, the transfer needle groove 43, the needle guard piece main body 45, the needle guard piece projection 451, the needle guard piece groove 452, the needle guard piece holding portion 46, the first projection 461, the second projection 462, the recess 463, the needle guard piece chamfered portion 47; the slit tooth 6a, the slit tooth 6b, the elongated body 61, the needle 611, the needle groove 6111, the support portion 612, the sewing groove 613, the engaging portion 62, the engaging protrusion 621, the raised portion 622, the fixing groove 623, the pressing plate 6c, the tooth holder 6d, and the tooth holder 6 e.

Detailed Description

Embodiments of the present invention will now be described with reference to the drawings, wherein like parts are designated by like reference numerals. The embodiments described below and the technical features of the embodiments may be combined with each other without conflict.

In the method of transferring fabric loops of the present invention, 3 parts are used, such as the transfer needle shown in fig. 1-4, the needle guard shown in fig. 5, and the seaming teeth shown in fig. 6-11.

Fig. 1 shows a perspective view of a transfer needle 4a of the present invention, which has a transfer needle body 41 having a transfer portion 42 at the head (one end contacting a loop of fabric) of the transfer needle body 41. The transfer needle body 41 is an elongated thin sheet, the transfer portion 42 is curved and offset from the axis of the transfer needle body 41, and preferably, the transfer portion 42 is arc-shaped, tapering from the end of the transfer needle body 41 and pointed at the tip. The transfer needle body 41 has a transfer needle protrusion 411 at a rear portion (an end away from the fabric loop), and the transfer needle protrusion 411 is engaged with a transfer tray of the fabric transfer device, pushes and pulls the transfer needle protrusion 411, and can move the transfer needle inward and inward in the radial direction, and can also move up and down to perform the transfer of the fabric loop.

Fig. 2 shows a perspective view of the transfer pin 4b of the present invention, which is different from the transfer pin 4a in that the shape thereof is symmetrical to the transfer pin 4 a. In use, a pair of transfer needles 4a, 4b are required to cooperate. Specifically, the transfer pins 4a and 4b are bonded together. The transfer needle body 41 is made into a sheet shape, so that the two bodies are jointed together, the volume is reduced, and the transfer needle is more environment-friendly.

Fig. 3 shows a state diagram of the transfer needles 4a, 4b in use. The respective transfer needle bodies 41 of the transfer needles 4a, 4b are fitted together, while the respective transfer portions 42 form a recess, a transfer needle recess 43, which transfer needle recess 43 is intended to receive the slot teeth of a fabric sewing device, the function and general structure of which are well known to the person skilled in the art and will not be described here.

Fig. 4 shows another embodiment of the transfer pin of the present invention, different from the first embodiment, the transfer pin body 41 has a certain thickness so that a groove, i.e., a transfer pin groove 43, can be opened at the head of the transfer pin body 41. The transfer needle recesses 43 are also used to accommodate the slit teeth. Preferably, the transfer needle groove 43 is asymmetrical with a notch at the end of the groove so that the tip of the knitting needle 1 can slide more smoothly into the transfer needle groove 43 (see fig. 6). The transfer needle body 41 has a transfer needle protrusion 411 at a rear portion (an end away from the fabric loop), and the transfer needle protrusion 411 is engaged with a transfer tray of the fabric transfer device, pushes and pulls the transfer needle protrusion 411, and can move the transfer needle inward and inward in the radial direction, and can also move up and down to perform the transfer of the fabric loop.

Fig. 5 shows the structure of the needle guard 4 c. The needle guard 4c is used in cooperation with the transfer needles 4a, 4 b. The needle guard 4c has a needle guard main body 45, and a needle guard holding portion 46 extends downward from the front end (one end contacting the stitches of the fabric) of the needle guard main body 45. The clip portion 46 has a first projection 461 and a second projection 462 forming a recess 463 therebetween. A needle guard beveling portion 47 is formed at the junction between the needle guard main body 45 and the needle guard holding portion 46. The needle guard clamping portion extends vertically downward from the needle guard chamfered portion (47).

The needle guard projection 451 is provided on the lower side of the rear end (end distant from the loop of the fabric) of the needle guard main body 45. The needle guard projection 451 is engaged to a transfer tray of a fabric transfer apparatus, and pushing and pulling the needle guard projection 451 can move a transfer needle radially inward and inward, and also can move up and down to perform transfer of a fabric loop.

The lower side of the needle guard body 45 has a plurality of needle guard grooves 452 for engagement with a transfer disc of a fabric transfer device. In use, the sewing needles 4a and 4b are inserted between the two needle guard pieces 4c and positioned in the gap formed by the needle guard piece holders 46 of the two needle guard pieces.

As shown in fig. 6, the slit tooth 6a has an elongated body 61 and an engaging portion 62, and the engaging portion 62 extends from the upper end of the elongated body 61, and the two are combined together to form a substantially 7-shaped overall shape. The elongated body 61 includes a needle portion 611 at a lower end and a support portion 612 at an upper end.

Fig. 7 shows a schematic view of the slit teeth 6a mounted on the tooth holder 6 e. Fig. 8 shows a schematic view of the slit teeth 6a mounted on the tooth holder 6 d. The toothrests 6e and 6d constitute a complete circular toothrest. Wherein the half-toothholder 6d in fig. 3 is turned 180 degrees downwards so that the two semicircular toothholders are aligned. The slit teeth 6a having a 7-shaped overall shape are mounted on the tooth holder 6e of the fabric transfer device, specifically, the elongated body 61 is fitted in the groove of the tooth holder 6e by hooking the engaging portion 62 to the groove of the tooth holder 6e, wherein the supporting portion 612 is completely fitted in the groove of the tooth holder 6e and only the needle portion 611 is exposed. Similarly, a slot tooth 6b (described below) is mounted on a tooth holder 6d of the fabric transfer device.

To enable the slot transfer teeth 6a and the slot teeth 6b to be mounted on the tooth holder 6e in a more fitting manner, the technical effect is ensured by the further detailed structure of the slot teeth 6a, which is described below with reference to fig. 1 and 4.

As shown in fig. 9, the height H of the support 612 matches the height of the tooth holder 6e, so that the support 612 is not exposed from the tooth holder 6e after installation, and only the needle 611 is exposed from the tooth holder 6 e. The width W of the support 612 matches the depth of the slot of the tooth holder 6e in the radial direction so that the outer surface of the support 612 is flush with the outer surface of the tooth holder 6e in the radial direction after installation, without sinking in and protruding out, the effect after installation being seen in fig. 7.

The engaging portion 62 has an engaging projection 621 on the lower side thereof, and a groove is formed between the engaging projection 621 and the supporting portion 612, so that the slit teeth 6a can be securely caught on the groove of the tooth holder 6 e. The upper surface of the engaging portion 62 has a fixing groove 623 to be engaged with the tooth holder 6e so that the slit tooth 6a can be securely coupled to the groove of the tooth holder 6 e. The tip of the engaging portion 62 has an upturned portion 622 for engaging with the toothholder 6e, thereby making contact therebetween tighter.

Fig. 10 shows the structure of the needle 611. The needle 611 has on its outer side (the side facing radially outward after being mounted on the tooth holder 6 e) a needle groove 6111, which needle groove 6111 is used for aligning the needle 611 of the slit tooth on the lower tooth holder after the tooth holder has been turned over 180 degrees, so that the needle 611 of the slit tooth on the upper tooth holder can overlap into the groove 6111 of the needle 611 of the slit tooth on the upper tooth holder, thereby making the following coil transfer smoother.

Fig. 11 shows a structure of another embodiment of a seaming tooth 6b, which has a seaming groove 613 on the outer side (the side facing radially outward after being mounted on a tooth holder 6 e) of an elongated body 61 of the seaming tooth 6b, the seaming groove 613 being used for accommodating a seaming needle of a toe sewing machine, and two seaming needles are alternately sewed to sew together the toe of the sock.

As shown in fig. 12, in use, the positional relationship between the slit tooth 6a, the transfer needle 4b, and the two needle guard pieces 4 c. The slit teeth 6a are inserted into a transfer needle groove 43 formed by the transfer needle 4a and the transfer needle 4b together, and the transfer needle 4a and the transfer needle 4b are inserted into a gap between two needle guard pieces 4 c.

The operation of the transfer needle of the present invention will be described with reference to fig. 13 to 29. The invention is described below with reference to socks as an example, but the invention can also be applied to other fabrics.

Fig. 13-16 show schematic diagrams of step S1 of the method of the present invention: the loops of the fabric on the hosiery knitting needles of the fabric are pressed down by a certain distance by means of the needle-protecting sheet, wherein the hosiery knitting needles penetrate into the gap formed by two adjacent needle-protecting sheets. As shown in fig. 13, after the sock is woven to the last turn, the fabric 3 is inside the tube 2 of the hosiery knitting machine, and the last turn of the fabric 3 is looped under the latch of the hosiery knitting needle 1. The needle guard 4c is moved radially inward to be positioned above the knitting needle 1 so that the knitting needle 1 is positioned below the gap formed by the two needle guard 4c used in pair.

As shown in fig. 14, the tube 2 is moved upward and the knitting needle 1 is also moved upward, and the cloth 3 is separated from the sinker 201 and approaches the needle guard 4 c. The distance of movement is such that the knitting needle 1 is located below the two needle guards 4c, wherein the transfer needles 4a, 4b are located above the two needle guards 4.

As shown in FIG. 15, the needle guard 4c is moved radially inward and the transfer needles 4a and 4b are moved radially outward so that the needle guard 4c is above the stitch and the needle guard 4c is moved downward to press the stitch on the knitting needle 1 below the latch. At the same time, the transfer needles 4a, 4b above the needle guard 4c are moved radially outward so as not to affect the up-down stroke of the transfer needle 1.

As shown in FIG. 16, the needle protecting piece 4c is moved down together with the transfer needles 4a and 4b, and the knitting needle 1 is passed through a gap formed between the two needle protecting pieces 4 c. The loops of the fabric 3 are pressed down a distance by the needle guard 4 c.

Fig. 17-19 show schematic diagrams of step S2 of the method of the present invention: the needle guard is moved to the loops of the fabric so that the loops are caught in the recesses of the needle guard.

In fig. 17, the needle guard 4c is moved radially outward, disengaging from the knitting needle 1 so as not to affect the up-down stroke of the transfer needle. It is possible to align the gap between the transfer needles 4a, 4b and the gap formed between the two needle guard pieces 4c up and down.

In fig. 18, the needle guard 4c is moved down together with the transfer needles 4a, 4b so that the depressions 463 of the needle guard 4c are aligned with the loops.

In fig. 19, the needle guard 4c is moved radially inward so that the knitting needle 1 is positioned in the gap formed by the two needle guards 4c and the stitch is positioned in the depression 463 of the needle guard 4 c.

Fig. 20-22 show schematic diagrams of step S3 of the method of the present invention: the needle protection sheet is moved upwards to drive the coil to move upwards, and the coil drives the latch of the sock knitting needle to turn upwards until the latch of the sock knitting needle abuts against the lower edge of the transfer needle.

In fig. 20, the needle guard 4c is moved upward together with the transfer needles 4a and 4b, the stitches of the fabric 3 are moved upward by the needle guard 4c, and finally the latch of the knitting needle 1 is also lifted by the needle guard 4c and finally abuts against the lower edges of the transfer needles 4a and 4 b.

In fig. 21, the needle guard 4c is moved radially outward and can be moved to the initial position of the needle guard 4c so as not to affect the up-down stroke of the transfer needle 1.

In fig. 22, the needle guard 4c is moved upward together with the transfer needles 4a and 4b, and the latch of the knitting needle is lifted.

Fig. 23 shows a schematic diagram of step S4 of the method of the present invention: the transfer needle is moved so that the needle head of the hosiery knitting needle is located in the transfer groove of the transfer needle.

In fig. 23, the transfer needles 4a, 4b are moved together radially inwards so that the tip portion of the knitting needle 1 rides in the transfer needle groove 43 formed in the transfer needles 4a, 4 b.

Fig. 24-26 show schematic diagrams of step S5 of the method of the present invention: moving the needle protecting sheet to the lower part of the coil to drive the coil to move upwards, so that the needle latch is closed, and the coil is transferred to the transfer needle

In fig. 24, the needle guard 4c is moved down below the stitch position of the fabric 3.

In fig. 25, the needle guard 4c is moved radially inwards so that the hosiery knitting needle is located in the gap formed by the two needle guard 4c, preferably with the upper edge of the needle guard 4c abutting against the loops of the fabric 3.

In fig. 26, the needle guard 4c is moved upward, the loop of the cloth 3 is moved upward, the latch of the knitting needle 1 is moved upward, and the opening of the knitting needle 1 is closed. The needle guard 4c is further moved so that the stitch is transferred to the transfer needles 4a, 4 b.

In fig. 27, the needle guard 4c is moved upward together with the transfer needles 4a, 4b to be separated from the knitting needle 1, and at this time, the stitches of the fabric 3 are fitted over the transfer needles 4a, 4b with the needle guard 4c held thereunder, thus being securely fitted over the transfer needles 4a, 4b, thereby facilitating subsequent operations such as transfer and inversion of the fabric.

In fig. 28, the knitting needle 1 is moved downward.

In fig. 29, the knitting needles and the sinker 201 are removed for the subsequent operations.

The above-mentioned embodiments are only preferred embodiments of the present invention, and the ordinary changes and substitutions performed by those skilled in the art within the technical scope of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A needle guard for a circular knitting machine, comprising:

the needle guard piece comprises a needle guard piece main body (45), a needle guard piece clamping part (46) extends downwards from the front end of the needle guard piece main body (45), the needle guard piece clamping part (46) is provided with a first protrusion (461) and a second protrusion (462), and a recess (463) is formed between the first protrusion (461) and the second protrusion (462).

2. A needle shield for a circular knitting machine according to claim 1,

a needle guard beveling part (47) is formed at the joint between the needle guard main body (45) and the needle guard clamping part (46),

the needle guard clamping portion (46) extends vertically downward from the needle guard chamfered portion (47).

3. A needle shield for a circular knitting machine according to claim 1,

the needle guard body (45) has a needle guard projection (451) on the lower side of the rear end thereof for engaging with an external device.

4. A needle shield for a circular knitting machine according to claim 1,

the needle guard main body (45) has a plurality of needle guard grooves (452) on the lower side thereof for engaging with an external device.

5. A needle shield for a circular knitting machine according to claim 1,

the needle guard clamping part (46) extends vertically downwards.

6. A needle shield for a circular knitting machine according to claim 3,

the needle guard projection (451) extends vertically downward.

Images